JP2008507232A - Apparatus and method for receiving a digital multimedia broadcast service in a mobile communication system - Google Patents

Abstract

  The present invention relates to an apparatus and method for receiving a broadcast service in a digital multimedia broadcast (DMB) system that provides user convenience. Such a DMB receiver includes a radio frequency (RF) receiver that receives a radio frequency signal transmitted from a base station, a modem receiver that measures the energy value of a pilot signal and achieves initial synchronization, and an energy value. A control unit for deriving a broadcast service channel status compared with a predetermined reference value and a display unit for displaying the broadcast service channel status derived from the control unit are included. The receiving apparatus and method can save power consumption by the mobile terminal of the DMB system confirming the current electric field condition and minimizing unnecessary operation. Also, only the simple initial synchronization is used to notify the user of the current electric field condition, thereby minimizing the inconvenience of showing an unclean broadcast in an environment where the channel condition is not favorable.

Description

  The present invention relates to a receiving apparatus and method in a mobile communication system, and more particularly to an apparatus and method for receiving a Digital Multimedia Broadcasting (DMB) service.

  Usually, digital broadcasting means a system that provides users with high image quality, high sound quality of CD level, and higher service instead of conventional analog broadcasting. Such digital broadcasting has been developed into two forms such as terrestrial broadcasting and satellite broadcasting. Here, terrestrial broadcasting means a digital broadcasting system that allows a user to receive a broadcasting service via a terrestrial repeater. On the other hand, satellite broadcasting means a digital broadcasting system that uses a satellite as a repeater to receive digital broadcasting. A typical example of the digital broadcasting is a DMB service. The DMB service is classified into two types such as terrestrial DMB and satellite DMB. As described above, the terrestrial DMB refers to a DMB system that provides a broadcast service to a user via a terrestrial repeater.

  On the other hand, the satellite DMB provides a broadcasting service using a satellite that is not a terrestrial repeater. Hereinafter, the satellite DMB service will be described in detail with reference to FIG. Referring to FIG. 1, a satellite DMB broadcasting center 100 transmits a broadcast signal through a Ku band (12 GHz to 13 GHz) in a time division multiplexing (TDM) system (reference numeral 102) and a code division multiplexing (Code Division Multiplex). ; CDM) method (reference numeral 104). Then, the DMB satellite 106 receives the broadcast signal and transmits the received signals 102 and 104 to a terrestrial receiving terminal 116 or a gap filler (Gap Filler) repeater 108 corresponding to a terrestrial repeater.

  The DMB satellite 106 converts the received broadcast signal into a CDM signal 112 having an S-band bandwidth of 2 to 3 GHz and a TDM signal 110 having a Ku band, and transmits them to the ground. The reason why the DMB satellite 106 transmits the broadcast signal to the gap filler repeater 108 is to allow the broadcast signal transmitted by the DMB satellite 106 to be received even in a shaded area such as underground. The gap filler repeater 108 receives the broadcast signal, converts it to S-band, and provides a service to the DMB terminal in the shaded area.

  The types of DMB terminals include fixed dedicated terminals such as HiFi type terminals that can be used mainly at home, mobile dedicated terminals used for vehicles, PDA (Personal There are portable terminals such as Digital Assistant), notebooks, and mobile phones.

  Since such a DMB terminal does not know whether the terminal can receive a DMB broadcast when the user selects a desired broadcast channel, it is inconvenient to use for a long time. was there. In addition, when the DMB terminal is located in a shaded area, if the channel condition is not good and the DMB terminal cannot use the DMB service, the operation for receiving the DMB broadcast is continuously performed. As a result, there is a problem that unnecessary power consumption is caused.

  In view of the above background, an object of the present invention is to provide a broadcast service receiving apparatus and method for indicating a received electric field condition to a user in a digital multimedia broadcast system.

  Another object of the present invention is to provide a receiving apparatus and method capable of minimizing power consumption when receiving a broadcast service in a digital multimedia broadcast system.

  In order to achieve the above object, according to the first aspect of the present invention, a super frame is composed of at least two frames, and the one frame is composed of a plurality of subframes. A subframe is a method for receiving a broadcast service by a mobile terminal in a digital multimedia broadcast (DMB) system in which a frame configured to have a pilot symbol period and a pilot data period is transmitted through a pilot signal. A first step of receiving a signal; a second step of deriving an electric field condition of a broadcast service channel by comparing a measured energy value of the pilot signal with a predetermined reference value in an initial synchronization operation; and A third step of indicating the electric field condition on the display unit of the mobile terminal; Characterized in that it Bei.

  The initial synchronization operation includes the step of synchronizing the pilot symbol and pilot data from the received pilot signal, the step of synchronizing the subframe from the received pilot signal, and the received pilot signal. And a step of synchronizing the superframe.

  The step of comparing the energy values of the pilot signal includes comparing the energy value Ep measured in the pilot symbol period with a predetermined reference value and a plurality of energy values measured while synchronizing the subframes. Among these, a step of comparing a difference value between the maximum energy value Emax and the second largest energy value Esec with a predetermined reference value, and a step of deriving an electric field condition of the broadcast service channel based on the compared value. It is characterized by comprising.

  The electric field condition is represented by a service impossible state or a predetermined step.

  According to the second aspect of the present invention, the superframe is composed of at least two frames, the one frame is composed of a plurality of subframes, and the one subframe is composed of a pilot symbol period and a pilot data period. A mobile terminal in a digital multimedia broadcast (DMB) system in which a base station transmits a frame configured to include a pilot signal through a pilot signal and receives a radio frequency signal (RF) transmitted from the base station ) A receiving unit, a modem receiving unit that measures the energy value of the pilot signal to achieve initial synchronization, a control unit that derives a broadcast service channel status by comparing the energy value with a predetermined reference value, and the control unit Display section showing the status of the broadcasting service channel derived from the above Characterized by including the.

  The modem receiver includes a searcher that searches for the pilot symbol period and the pilot data period of the pilot signal, and a signal rake receiver that measures an energy value of the pilot signal.

  The step of synchronizing the initial synchronization includes the step of synchronizing the synchronization of pilot symbols and pilot data from the received pilot signal, the step of synchronizing the subframe from the received pilot signal, and the received pilot signal. To synchronize the superframe.

  The control unit compares the energy value Ep measured in the pilot symbol period with the predetermined reference value, and among the plurality of energy values measured during synchronization of the subframe, the maximum energy value Emax And the second largest energy value Esec are compared with a predetermined reference value, and the electric field condition of the broadcast service channel is derived based on the compared value.

  According to an embodiment of the present invention, power consumption can be reduced by the mobile terminal of the DMB system confirming the current electric field condition and minimizing unnecessary operation. Also, only the simple initial synchronization is used to notify the user of the current electric field condition, thereby minimizing the inconvenience of showing an unclean broadcast in an environment where the channel condition is not favorable.

  Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description, for the purpose of clarifying only the gist of the present invention, a specific description regarding related known functions or configurations is omitted.

  FIG. 2 is a block diagram illustrating a configuration of a DMB terminal according to a preferred embodiment of the present invention. Referring to FIG. 2, the DMB terminal receives a signal transmitted as a terrestrial repeater via a DMB satellite or a gap filler, and measures the energy value of each frame from the received signal of the RF receiver 210. The modem receiving unit 230, the control unit 250 for checking the measured energy value and controlling the initial synchronization process of the terminal, and whether the service channel output from the control unit 250 can be received. And a display unit 270 for visually displaying the guide information. The guidance information is shown in a service impossible state or a predetermined step in comparison with a predetermined reference value.

  Hereinafter, in order to help understanding of the present invention, the configuration of the pilot channel in the DMB service is first described, and then the configuration of the DMB terminal according to the present invention is described in more detail.

  FIG. 3 shows a structure of a super frame transmitted through a pilot channel in a general DMB service. Referring to FIG. 3, the super frame 310 includes six frames 311 to 321, each of the frames 311 to 321 includes 51 subframes 350, and each of the subframes 350 includes pilot symbols (Pilot). Symbol; PS) section and pilot data (Pilot Data; PD) section. Accordingly, the pilot signal includes pilot symbols and pilot data.

  The subframe has a frame cycle of 250 μs. Also, since one frame 330 is composed of 51 subframes, it has a frame cycle of 12.750 ms. Accordingly, the super frame 310 composed of six frames 311 to 321 has a frame cycle of 76.5 ms.

  Among the pilot signals, the pilot symbol includes synchronization information of the subframe, and the pilot data includes not only synchronization information of each frame 330 and superframe 310 but also error correction codes and decoding of the broadcast channel. For broadcast information.

Meanwhile, the controller 250 of FIG. 2 performs initial synchronization of the system using the energy value measured by the modem receiver 230. The process of matching the initial synchronization includes a pilot symbol detection process, a unique word detection process, and a frame count detection process. The pilot symbol detection process for synchronizing the subframe 350 is performed by measuring the energy value of each pilot symbol period 331, 335... And pilot data period 333, 337. A unique word detection process for synchronizing each frame 330 is performed by detecting the first pilot data section (D ₁ ) 333 of the pilot signal. In the frame count detection process, the super frame 310 is synchronized by detecting the _second pilot data interval (D ₂ ) 337 of the pilot signal. Hereinafter, a method for indicating the initial synchronization detection process and the terminal electric field state will be described in more detail with reference to FIG.

  FIG. 4 is a block diagram showing an internal configuration of modem receiving section 230 shown in FIG. In the following description, an initial synchronization detection process using a received pilot signal will be described with reference to FIGS. 3 and 4.

  Referring to FIG. 4, the modem receiving unit 230 has a searcher 231 that performs an operation of detecting a pilot symbol period and a pilot data period of a pilot signal, and an energy value for matching the frame synchronization of the pilot signal. A rake receiver 233 for measuring and accumulating is included inside.

  First, a rake receiver 233 receiving a pilot signal confirms a pilot symbol period and a pilot data period in each of the subframes 350, 351,. .. And pilot data sections 333, 337,... Are configured to have the same length. The pilot symbol period is coded with one number, and the pilot data period is coded with a number mixed with ‘0’ and ‘1’. Accordingly, the rake receiver 233 accumulates energy for each section and transmits the energy value to the control unit 250. As a result, the control unit 250 recognizes a larger value of the two energy values as the pilot symbol energy value Ep and recognizes a smaller value as the pilot data energy value Ed. In order to check whether the synchronization of the subframe 350 is accurate, the control unit 250 has the Ep value larger than the Ed value, and the difference between the Ep value and the Ed value is a predetermined reference value (Threshold ) Check if it is larger. If such a condition is satisfied, the controller 250 recognizes that the pilot symbol detection operation has been completed, and proceeds with a unique word detection process as the next step. However, if the above condition is not satisfied, the control unit 250 repeats the above-described process for a predetermined time limit. If the above condition is not satisfied even after the above process is repeated, the control unit 250 displays a message indicating “service cannot be received” on the display unit 270.

  In the unique word detection process, a unique word pattern value already known by the rake receiver 233 and an energy value corresponding to the degree of correlation between the pilot data are measured in at least one frame section. . Thereafter, the rake receiver 233 selects the four largest values among the measured correlation degrees of the pilot data and transmits them to the control unit 250. Then, the control unit 250 confirms whether the largest energy value Emax is larger than a predetermined reference value among the correlation degrees transmitted from the rake receiver 233, and the second largest energy value Emax and the second energy value Emax are checked. It is confirmed whether or not the difference value from the large energy value Esec is larger than a predetermined reference value. If such a condition is satisfied, the control unit 250 determines that a unique word has been detected, and determines that synchronization between frames is correct. However, if the above condition is not satisfied, the control unit repeats the same process for a predetermined time if the difference value does not satisfy the reference value as in the pilot symbol detection operation. If the above condition is not satisfied even after the repetition, the control unit 250 displays a message indicating “service cannot be received” on the display unit 270.

In the frame counting process, a frame count value is transmitted and input to D ₂ 337 which is a part of pilot data, and the transmitted frame count value is read and notified to the control unit 250.

In reading the frame count value, D ₂ 337 is composed of a total of 32 bits, and a 4-bit frame count value coded with “−1” or “1” is repeatedly input eight times. . The frame count detector accumulates the energy value of each of the 4 bits, regards the largest value of each bit as '1', and detects the frame count value. For example, when the frame count value is “2”, the value of D ₂ 337 as “−1−11-1” is repeated eight times. Accordingly, by accumulating the energy value in the frame counting process, the frame count detector can detect “2”, and the detected frame count value is provided to the controller 250.

  When all the initial synchronization processes are completed, the controller 250 compares the energy value measured for each initial synchronization operation with a reference value for the current channel state, and displays the current channel electric field condition so that the user can recognize the current channel field condition. Displayed on the part 270. The current electric field state may be indicated as 'broadcast reception is not possible' or may be indicated in a predetermined step-by-step state as compared with the reference value.

  A method for receiving a digital multimedia broadcast (DMB) service according to a preferred embodiment of the present invention will be described with reference to FIGS.

  FIG. 5 is a flowchart for a method of receiving a DMB service according to a preferred embodiment of the present invention.

  Referring to FIG. 5, when the pilot signal received from the RF receiver 210 is input to the modem receiver 230, the pilot symbol detection operation proceeds in step S501. First, the search unit 231 of the modem receiving unit 230 measures and accumulates the energy value Ep of each pilot symbol section and the energy value Ed of the pilot data section. In step S503, the control unit 250 that has received the energy value checks whether the Ep value is larger than the Ed value and the difference value between the Ep value and the Ed value is larger than a predetermined reference value. If such a condition is satisfied, control unit 250 proceeds to step S507 with synchronization of subframes. However, if the above condition is not satisfied, the control unit 250 confirms whether or not a predetermined time limit has elapsed in step S505. If the time limit has not elapsed, the pilot symbol detection process is repeated. However, if the time limit is exceeded, the control unit 250 proceeds to step S515, and displays a message indicating “service is not possible” on the display unit of the DMB terminal.

  In the pilot detection operation process, the current electric field condition can be confirmed with the energy value accumulated in the pilot symbol period. In other words, as described above, the energy of the current received pilot symbol interval accumulates the energy of the pilot symbol. The energy value accumulated and measured in this manner varies depending on the electric field condition. That is, when the electric field condition is good, a large energy value is derived, and when the electric field condition is not good, a small energy value is derived. Therefore, the current electric field condition can be confirmed using the energy value. The energy value is stored in the control unit 250 in a table format and displayed as a message or guide information corresponding to the current electric field condition on the display unit of the DMB terminal.

  When the pilot detection operation is completed, a unique word detection operation is performed in step S507. The rake receiver 233 measures a known unique word pattern value and an energy value corresponding to the degree of correlation between the pilot data in at least one frame section 330. Thereafter, in step S509, the control unit 250 searches for the largest value Emax and the second largest value Esec among the energy values, and sets a difference value between the Emax value and the Esec value as a predetermined reference. Compare with value.

  When the difference value exceeds the reference value, the control unit 250 synchronizes the frame 330 with the Emax value and proceeds to step S513. However, if the difference value does not exceed the reference value, in step S511, the control unit 250 checks whether the unique word detection time has passed a predetermined time limit. If the time limit has not elapsed, the unique word detection operation is repeated. On the contrary, if the time limit is exceeded, the control unit 250 proceeds to step S515, and displays a message indicating “service is not possible” on the display unit of the DMB terminal.

In the unique word detection operation, the Emax value is measured using a certain pattern known by the receiver and the correlation with D ₁ 333, so that the Emax value can indicate the current electric field condition. When the Emax value passes the reference value, the Esec value can be confirmed, and it can be confirmed whether the Esec value has also passed the reference value. If the Esec value also passes the reference value, this means that the unique word detection operation is not properly performed, and the electric field condition is not so good. However, if the Esec value does not pass the reference value, the current electric field state can be confirmed using the difference between the Emax value and the Esec value. That is, when the Emax value is larger than the Esec value, this means that the current electric field condition is good. The control unit 250 has a difference value between the Emax value and the Esec value in a table format, compares the Emax value detected by the unique word detection operation and the Esec value with the table, and determines the current electric field. The status is displayed on the display unit of the DMB terminal.

In the unique word detection operation, when the synchronization of the frame 330 is synchronized, the control unit 250 reads the data value of the _second pilot data (D ₂ ) in step S509 to synchronize the super frame 310.

  By using the above-described process, the energy value measured during the initial synchronization operation is compared with a reference value determined for each predetermined step, so that the user can recognize the current electric field condition. The current electric field state is displayed on the section. Thereafter, in step S517, the DMB terminal stops all operations and waits until the user decides no selection.

  Here, there are various methods for indicating the current electric field condition. The electric field state can be indicated by the energy value measured in the pilot symbol detection process, or by comprehensively considering the energy value measured in each of the pilot symbol detection process and the unique word detection process. The electric field situation can also be shown.

  In the present invention, not only the user can recognize the broadcast reception state of the DMB terminal, but also when the DMB terminal is in the initial synchronization process and the electric field condition is not good, before the user issues any command, the following process is performed. Since it does not proceed, power consumption can be minimized.

  In the detailed description of the present invention, specific embodiments have been described. Needless to say, various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be defined by the claims and their equivalents.

It is the schematic which shows the network structure of a DMB system. FIG. 2 is a block diagram illustrating a configuration of a DMB terminal according to a preferred embodiment of the present invention. It is the schematic which shows the pilot channel structure of a DMB system. It is a block diagram which shows the internal structure of the modem receiving part by preferable embodiment of this invention. 5 is a flowchart for a method of receiving a DMB service according to a preferred embodiment of the present invention.

Explanation of symbols

210 RF receiver 230 Modem receiver 231 Search unit 233 Rake receiver 250 Control unit 270 Display unit

Claims (13)

The super frame is composed of at least two frames, the one frame is composed of a plurality of subframes, and the one subframe is a frame configured to have a pilot symbol period and a pilot data period. A method for a mobile terminal to receive a broadcast service in a digital multimedia broadcast (DMB) system that transmits through a pilot signal, comprising:
Receiving the pilot signal;
Deriving an electric field condition of the broadcast service channel by comparing the measured energy value of the pilot signal with a predetermined reference value in an initial synchronization operation;
And displaying the electric field condition on a display unit of the mobile terminal. The initial synchronization operation is
Synchronizing the pilot symbols and pilot data from the received pilot signal;
Synchronizing the subframes from the received pilot signal;
The method of claim 1, further comprising the step of synchronizing the superframe from the received pilot signal. The step of comparing the energy values of the pilot signals includes:
Comparing the energy value Ep measured in the pilot symbol interval with a predetermined reference value;
The method of claim 2, further comprising: deriving a field condition of a broadcast service channel based on the compared value. The step of comparing the energy values of the pilot signals includes:
Comparing the energy value Ep measured in the pilot symbol interval with a predetermined reference value;
Comparing a difference value between a maximum energy value Emax and a second largest energy value Esec among a plurality of energy values measured while synchronizing the subframes with a predetermined reference value;
3. The method according to claim 2, further comprising the step of deriving an electric field condition of a broadcast service channel based on the compared value.   The method of claim 1, wherein the electric field condition is represented by an inability to service state or a stage compared with a predetermined reference value.   The method according to claim 1, wherein the predetermined reference value is stored in a control unit of the mobile terminal. The super frame is composed of at least two frames, the one frame is composed of a plurality of subframes, and the one subframe is a frame configured to have a pilot symbol period and a pilot data period. A mobile terminal in a digital multimedia broadcast (DMB) system transmitted by a base station through a pilot signal,
A radio frequency (RF) receiver that receives a radio frequency signal transmitted from the base station;
A modem receiver for measuring the energy value of the pilot signal to achieve initial synchronization; and
A controller that derives a broadcast service channel status by comparing the energy value with a predetermined reference value;
A mobile terminal comprising: a display unit indicating the broadcast service channel status derived from the control unit. The modem receiver is
A searcher for searching for the pilot symbol period and the pilot data period of the pilot signal;
The mobile terminal according to claim 7, further comprising a signal rake receiver for measuring an energy value of the pilot signal. The process of matching the initial synchronization in the modem receiving unit,
The pilot symbol and pilot data are synchronized from the received pilot signal, the subframe is synchronized from the received pilot signal, and the superframe is synchronized from the received pilot signal. Mobile terminal. The controller is
10. The electric field status of the broadcast service channel is derived based on the compared value by comparing an energy value Ep measured in the pilot symbol period with the predetermined reference value. Mobile terminal. The controller is
The energy value Ep measured in the pilot symbol period is compared with the predetermined reference value, and among the plurality of energy values measured during synchronization of the subframe, the maximum energy value Emax is the second largest. The mobile terminal according to claim 9, wherein a difference value with respect to the energy value Esec is compared with a predetermined reference value, and an electric field condition of the broadcast service channel is derived based on the compared value. The reference value is
The mobile terminal according to claim 7, wherein the mobile terminal is stored in advance in a memory of the control unit. The electric field status of the broadcast service channel is:
The mobile terminal according to claim 7, wherein the mobile terminal is represented in a service incapable state or a stage compared with a predetermined reference value.

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